Structure, mechanism and engineering of a nucleotidylyltransferase as a first step toward glycorandomization.

Metabolite glycosylation is affected by three classes of enzymes: nucleotidylyltransferases, which activate sugars as nucleotide diphospho-derivatives, intermediate sugar-modifying enzymes and glycosyltransferases, which transfer the final derivatized activated sugars to aglycon substrates. One of the first crystal structures of an enzyme responsible for the first step in this cascade, alpha-D-glucopyranosyl phosphate thymidylyltransferase (Ep) from Salmonella, in complex with product (UDP-Glc) and substrate (dTTP) is reported at 2.0 A and 2.1 A resolution, respectively. These structures, in conjunction with the kinetic characterization of Ep, clarify the catalytic mechanism of this important enzyme class. Structure-based engineering of Ep produced modified enzymes capable of utilizing 'unnatural' sugar phosphates not accepted by wild type Ep. The demonstrated ability to alter nucleotidylyltransferase specificity by design is an integral component of in vitro glycosylation systems developed for the production of diverse glycorandomized libraries.

Crystal structure of an Eph receptor-ephrin complex.

The Eph family of receptor tyrosine kinases and their membrane-anchored ephrin ligands are important in regulating cell-cell interactions as they initiate a unique bidirectional signal transduction cascade whereby information is communicated into both the Eph-expressing and the ephrin-expressing cells. Initially identified as regulators of axon pathfinding and neuronal cell migration, Ephs and ephrins are now known to have roles in many other cell-cell interactions, including those of vascular endothelial cells and specialized epithelia. Here we report the crystal structure of the complex formed between EphB2 and ephrin-B2, determined at 2.7 A resolution. Each Eph receptor binds an ephrin ligand through an expansive dimerization interface dominated by the insertion of an extended ephrin loop into a channel at the surface of the receptor. Two Eph-Ephrin dimers then join to form a tetramer, in which each ligand interacts with two receptors and each receptor interacts with two ligands. The Eph and ephrin molecules are precisely positioned and orientated in these complexes, promoting higher-order clustering and the initiation of bidirectional signalling.

Crystal structure of eukaryotic DNA ligase-adenylate illuminates the mechanism of nick sensing and strand joining.

Chlorella virus DNA ligase is the smallest eukaryotic ATP-dependent ligase known; it has an intrinsic nick-sensing function and suffices for yeast cell growth. Here, we report the 2.0 A crystal structure of the covalent ligase-AMP reaction intermediate. The conformation of the adenosine nucleoside and contacts between the enzyme and the ribose sugar have undergone a significant change compared to complexes of T7 ligase with ATP or mRNA capping enzyme with GTP. The conformational switch allows the 3' OH of AMP to coordinate directly the 5' PO(4) of the nick. The structure explains why nick sensing is restricted to adenylated ligase and why the 5' phosphate is required for DNA binding. We identify a metal binding site on ligase-adenylate and propose a mechanism of nick recognition and catalysis supported by mutational data.

Crystal structure of the ligand-binding domain of the receptor tyrosine kinase EphB2.

The Eph receptors, which bind a group of cell-membrane-anchored ligands known as ephrins, represent the largest subfamily of receptor tyrosine kinases (RTKs). They are predominantly expressed in the developing and adult nervous system and are important in contact-mediated axon guidance, axon fasciculation and cell migration. Eph receptors are unique among other RTKs in that they fall into two subclasses with distinct ligand specificities, and in that they can themselves function as ligands to activate bidirectional cell-cell signalling. We report here the crystal structure at 2.9 A resolution of the amino-terminal ligand-binding domain of the EphB2 receptor (also known as Nuk). The domain folds into a compact jellyroll beta-sandwich composed of 11 antiparallel beta-strands. Using structure-based mutagenesis, we have identified an extended loop that is important for ligand binding and class specificity. This loop, which is conserved within but not between Eph RTK subclasses, packs against the concave beta-sandwich surface near positions at which missense mutations cause signalling defects, localizing the ligand-binding region on the surface of the receptor.

RNA polymerase II transcription initiation: a structural view.

In eukaryotes, RNA polymerase II transcribes messenger RNAs and several small nuclear RNAs. Like RNA polymerases I and III, polymerase II cannot act alone. Instead, general initiation factors [transcription factor (TF) IIB, TFIID, TFIIE, TFIIF, and TFIIH] assemble on promoter DNA with polymerase II, creating a large multiprotein-DNA complex that supports accurate initiation. Another group of accessory factors, transcriptional activators and coactivators, regulate the rate of RNA synthesis from each gene in response to various developmental and environmental signals. Our current knowledge of this complex macromolecular machinery is reviewed in detail, with particular emphasis on insights gained from structural studies of transcription factors.

Crystal structure of a human TATA box-binding protein/TATA element complex.

The TATA box-binding protein (TBP) is required by all three eukaryotic RNA polymerases for correct initiation of transcription of ribosomal, messenger, small nuclear, and transfer RNAs. The cocrystal structure of the C-terminal/core region of human TBP complexed with the TATA element of the adenovirus major late promoter has been determined at 1.9 angstroms resolution. Structural and functional analyses of the protein-DNA complex are presented, with a detailed comparison to our 1.9-angstroms resolution structure of Arabidopsis thaliana TBP2 bound to the same TATA box.

Crystal structure of a TFIIB-TBP-TATA-element ternary complex.

The crystal structure of the transcription factor IIB (TFIIB)/TATA box-binding protein (TBP)/TATA-element ternary complex is described at 2.7 A resolution. Core TFIIB resembles cyclin A, and recognizes the preformed TBP-DNA complex through protein-protein and protein-DNA interactions. The amino-terminal domain of core TFIIB forms the downstream surface of the ternary complex, where it could fix the transcription start site. The remaining surfaces of TBP and the TFIIB can interact with TBP-associated factors, other class II initiation factors, and transcriptional activators and coactivators.

2.1 A resolution refined structure of a TATA box-binding protein (TBP).

The three-dimensional structure of a TATA box-binding protein (TBP2) from Arabidopsis thaliana has been refined at 2.1 A resolution. TBPs are general eukaryotic transcription factors that participate in initiation of RNA synthesis by all three eukaryotic RNA polymerases. The carboxy-terminal portion of TBP is a unique DNA-binding motif/protein fold, adopting a highly symmetric alpha/beta structure that resembles a molecular saddle with two stirrup-like loops. A ten-stranded, antiparallel beta-sheet provides a concave surface for recognizing class II nuclear gene promoters, while the four amphipathic alpha-helices on the convex surface are available for interaction with other transcription factors. The myriad interactions of TBP2 with components of the transcription machinery are discussed.

Co-crystal structure of TBP recognizing the minor groove of a TATA element.

The three-dimensional structure of a TATA-box binding polypeptide complexed with the TATA element of the adenovirus major late promoter has been determined by X-ray crystallography at 2.25 A resolution. Binding of the saddle-shaped protein induces a conformational change in the DNA, inducing sharp kinks at either end of the sequence TATAAAAG. Between the kinks, the right-handed double helix is smoothly curved and partially unwound, presenting a widened minor groove to TBP's concave, antiparallel beta-sheet. Side-chain/base interactions are restricted to the minor groove, and include hydrogen bonds, van der Waals contacts and phenylalanine-base stacking interactions.

X-ray crystallographic studies of eukaryotic transcription factors.

Our X-ray crystallographic work on eukaryotic transcription factors traverses the entire length of a typical class II nuclear gene promoter, including the TATA-box-binding protein, two b/HLH/Z promoter proximal binding factors (Max and USF), and an enhancer-binding factor (HNF-3 gamma). These high-resolution studies of specific protein/DNA interactions will be extended to include homologous proteins complexed with similar oligonucleotides and a systematic examination of the roles of individual amino acids and bases implicated in specific DNA binding. In the longer term, we will turn our attention to the myriad of protein/protein interactions occurring within TFIID and the PIC, and between the PIC and factors binding to promoter proximal and distal enhancer elements.

Crystal structure of TFIID TATA-box binding protein.

The structure of a central component of the eukaryotic transcriptional apparatus, a TATA-box binding protein (TBP or TFIID tau) from Arabidopsis thaliana, has been determined by X-ray crystallography at 2.6 A resolution. This highly symmetric alpha/beta structure contains a new DNA-binding fold, resembling a molecular 'saddle' that sits astride the DNA. The DNA-binding surface is a curved, antiparallel beta-sheet. When bound to DNA, the convex surface of the saddle would be presented for interaction with other transcription initiation factors and regulatory proteins.